Combustion chamber of an internal combustion engine

ABSTRACT

An internal combustion engine comprises a first raised portion formed on the inner wall of the cylinder head, a second raised portion formed on the top face of the piston at a position opposite to the first raised portion with respect to the axis of the piston, and a third raised portion formed on the inner wall of the cylinder head above the second raised portion. A first flat squish area is formed between the flat peripheral top face of the piston and the flat bottom face of the first raised portion. A second spherical shell shape squish area is formed between the spherical bottom wall of the third raised portion and the spherical rear face of the second raised portion. A surface area ratio of the sum of the first and second squish areas formed on the inner wall of the cylinder head and the first and second squish areas formed on the top face of the piston to the sum of the cross-sectional area of the cylinder bore and the surface area of the inner wall of the cylinder head, except for the surface area of the vertical side wall of the first raised portion, is in the range of 30 percent to 50 percent.

DESCRIPTION OF THE INVENTION

The present invention relates to a construction of the combustion chamber of an internal combustion engine.

As a method of simultaneously reducing the amount of harmful HC, CO and NO_(x) components in the exhaust gas, a method of using a lean air-fuel mixture has been known. In addition, as a method of reducing the amount of harmful NO_(x) components in the exhaust gas, a method of using a mixture containing the recirculated exhaust gas therein has been known. However, in either the case wherein a lean air-fuel mixture is used or the case wherein a mixture containing the recirculated exhaust gas therein is used, a problem occurs in that, since the flame speed of either mixture is very low and the burning velocity is thus low, a stable combustion cannot be obtained. In order to obtain a stable combustion by using a lean air-fuel mixture or a mixture containing the recirculated exhaust gas therein, it is necessary to increase the burning velocity. As a method of increasing the burning velocity, a method of creating a strong turbulence in the combustion chamber can be used. As an engine which is capable of increasing the burning velocity by creating a turbulence in the combustion chamber, the inventor has proposed an engine which comprises a first downwardly projecting raised portion formed on the periphery of the inner wall of the cylinder head and having a flat bottom face so as to form a first squish area between the flat bottom face of the first raised portion and a flat peripheral portion of the top face of the piston when the piston approaches the top dead center. In addition, this engine further comprises a second upwardly projecting raised portion formed on the top face of the piston at a position opposite to the flat peripheral portion of the top face of the piston with respect to the axis of the cylinder so as to form a second squish area between the inner wall of the cylinder head and the rear face of the second raised portion when the piston approaches the top dead center. In addition, in this engine, the seond raised portion has an inclined front face which is exposed to the combustion chamber and smoothly connected to the flat peripheral portion of the piston. At the end of the compression stroke, a swirl motion rotating about the horizontal axis is created in the combustion chamber by a pair of squish flows spouted from the first and the second squish areas, respectively, in the combustion chamber.

However, in the above-mentioned engine, it is impossible to create a satisfactory strong swirl motion in the combustion chamber. As a result of the experiments conducted by the inventor with respect to an engine having the above-mentioned construction, it has been proven that, in order to create a strong swirl motion rotating about the horizontal axis in the combustion chamber, it is necessary to set the surface areas of the first squish area and the second squish area at an optimum area, and that since the surface areas of the first squish area and the second squish area of the above-mentioned engine are excessively small, a satisfactory strong swirl motion cannot be created in the combustion chamber.

An object of the present invention is to provide an internal combustion engine capable of an extremely strong swirl motion rotating about the horizontal axis.

According to the present invention, there is provided an internal combustion engine comprising: a cylinder block having a cylinder bore therein; a cylinder head mounted on the cylinder block and having an inner wall; a first raised portion having on its lower end a flat bottom face and being formed on the periphery of the inner wall of the cylinder head so as to project downwards; a piston reciprocally movable in the cylinder bore and having a top face which has a flat peripheral portion approachable to the flat bottom face so as to create a first squish area therebetween at the end of the compression stroke for spouting out a first squish flow along the top face of the piston, the inner wall of the cylinder head and the top face of the piston defining a combustion chamber therebetween; an intake valve movably mounted on the cylinder head for guiding a combustible mixture into the combustion chamber; an exhaust valve movably mounted on the cylinder head for discharging exhaust gas into the atmosphere; a second raised portion formed on the top face of the piston at a position opposite to the first raised portion with respect to an axis of the piston and having a rear face and a front face exposed to the combustion chamber, the rear face being approachable to the inner wall of the cylinder head so as to create a second squish area therebetween at the end of the compression stroke for spouting out a second squish flow which moves forwards in the upper interior of the combustion chamber in the direction opposite to the spouting direction of the first squish flow, the first and second squish flows cooperating with each other to create a strong swirl motion rotating about a horizontal axis in the combustion chamber, and; a spark plug having a spark gap located in the combustion chamber, wherein the improvement comprises a third raised portion formed on the inner wall of the cylinder head above the second raised portion and having a bottom wall which cooperates with the rear face of the second raised portion for creating the second squish area therebetween, the first raised portion having an approximately vertical side wall exposed to the combustion chamber, a surface area ratio of the sum of the first and second squish areas formed on the inner wall of the cylinder head and the first and second squish areas formed on the top face of the piston to the sum of the cross-sectional area of the cylinder bore and the surface area of the inner wall of the cylinder head, except for the surface of the vertical side wall of the first raised portion, being in the range of 30 percent to 50 percent.

The present invention may be more fully understood from the description of a preferred embodiment of the invention set forth below, together with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional side view of an internal combustion engine according to the present invention;

FIG. 2 is a bottom view taken along the line II--II in FIG. 1;

FIG. 3 is a cross-sectional side view taken along the line III--III in FIG. 1, and;

FIG. 4 is a perspective view of the piston illustrated in FIG. 1.

DESCRIPTION OF A PREFERRED EMBODIMENT

Referring to FIGS. 1 through 3, 1 designates a cylinder block, 2 a piston reciprocally movable in the cylinder block 1; 3 designates a cylinder head fixed onto the cylinder block 1 via a gasket 4; 5 designates a combustion chamber formed between the top face of the piston 2 and the inner wall of the cylinder head 3; 6 designates an intake valve, 7 an intake port, 8 an exhaust valve, 9 an exhaust port, 10 a spark plug, and 11 an electrode of the spark plug 10. As is illustrated in FIGS. 1 through 3, the inner wall of the cylinder head 3 has an annular flat surface 12 which extends circumferentially over the entire periphery of the inner wall of the cylinder head. The flat surface portion 12a of the annular flat surface 12, which is located on the left side in FIG. 2, has a uniform width illustrated by the arrow A in FIG. 2, while flat surface portions 12b and 12c of the annular flat surface 12, which are located on the right side in FIG. 2, have widths which are wider than the width A of the flat surfacd portion 12a as illustrated by the arrows B and C in FIG. 2, respectively. In addition, from FIG. 2, it will be understood that the flat surface portion 12b located near the exhaust valve 8 has the width B which is wider than the width C of the flat surface portion 12c located near the intake valve 6. As is illustrated in FIGS. 1, 3 and 4, an annular flat surface 13 arranged to face the annular flat surface 12 of the cylinder head 3 and having a shape which is approximately equal to that of the annular flat surface 12 is formed on the top face of the piston 2. That is, the flat surface portion 13a of the annular flat surface 13, which is formed on the top face of the piston 2 so as to face the flat surface portion 12a of the cylinder head 3, has a uniform width which is approximately equal to the width A of the annular flat surface 12, and the flat surface portions 13b and 13c of the annular flat surface 13, which are formed on the top face of the piston 2 so as to face the flat surface portions 12b and 12c, respectively, have widths which are wider than the width of the flat surface portion 13a of the piston 2. Consequently, when the piston 2 is positioned at the top dead center as illustrated in FIG. 1, a flat and annular squish area S is formed between the annular flat surface 12 of the cylinder head 3 and the annular flat surface 13 of the piston 2. As illustrated in FIGS. 1 and 3, the top face 14 of the combustion chamber 5 has a spherical shape; in addition, the side wall 15 of the combustion chamber 5 extends approximately vertically from the flat surface portions 12b, 12c of the cylinder head 3 to the top face 14 of the combustion chamber 5. A downwardly projecting raised portion 16 is formed on the top face 14 at a position opposite to the spark plug 10 with respect to the axis of the piston 2, and the bottom wall 16a of the raised portion 16 has a spherical shape. The lower edge of the bottom wall 16a of the raised portion 16 is connected to the flat surface portion 12a of the cylinder head 3, and the upper edge of the bottom wall 16a is connected to the top face 14 of the combustion chamber 5 via a steeply inclined side wall 16b arranged to be exposed to the combustion chamber 5. A raised portion 17 is formed on the top face of the piston 2 at a position opposite to the flat surface portions 13b, 13c of the piston with respect to the axis of the piston 2, and the rear face 18 of the raised portion 17 has a spherical shape complementary to the shape of the bottom wall 16a of the raised portion 16. In addition, the lower edge of the rear face 18 of the raised portion 17 is connected to the flat surface portion 13a of the piston 2. Consequently, when the piston 2 is positioned at the top dead center as illustrated in FIG. 1, a spherical shell squish area T is formed between the bottom wall 16a of the raised portion 16 and the rear face 18 of the raised portion 17. In addition, a flat and shallow depression 19 is formed in the central portion of the top face of the piston 2 at a position located inside of the flat surface portions 13b, 13c of the piston 2, and the raised portion 17 has an inclined front face 20 extending from the flat depression 19 to a ridge 21 of the raised portion 17 and arranged to be exposed to the combustion chamber 5. As is illustrated in FIG. 1, the ridge 21 of the raised portion 17 is rounded. As is illustrated in FIGS. 1 through 3, a semi-cylindrical recess 22, which has a particular shape wherein the lower end of the semi-cylinder is obliquely cut, is formed on the top face 14 of the combustion chamber 5 at a position opposite to the squish area T with respect to the axis of the piston 2, and the electrode 11 of the spark plug 10 is arranged in the recess 22. Consequently, the electrode 11 of the spark plug 10 is partially enclosed by a vertically extending semi-cylindrical wall 23. As mentioned hereinafter, when the piston 2 approaches the top dead center, a pair of squish flows shown by the arrows F and G in FIG. 1 is spouted from the squish areas S and T, respectively, and the electrode 11 of the spark plug 10 is arranged on an extension of the squish area T so that the squish flow G impinges directly upon the electrode 11. However, it should be noted that, when the downward movement of the piston 2 is started, a pair of gas streams flowing towards the squish areas S and T in directions which are opposite to those of the squish flows G and F, respectively, is created in the combustion chamber 5.

During operation, at the time of the intake stroke, when the downward movement of the piston 2 is started, the pair of gas streams flowing towards the squish areas S and T at a high speed in directions which are opposite to those of the squish flows G and F, respectively, is created in the combustion chamber 5 due to the temporary pressure drop within the squish areas S and T, and a strong turbulence is thus created in the combustion chamber 5. As a result of this, the air-fuel ratio of a lean mixture or a mixture containing the recirculated exhaust gas therein in the combustion chamber 5 becomes uniform over the entire region of the combustion chamber 5. In the case wherein the mixture contains the recirculated exhaust gas therein, the air-fuel mixture is completely mixed with the recirculated exhaust gas due to the above-mentioned strong turbulence. After this, at the time of the compression stroke, when the piston 2 approaches the top dead center, the squish flows F and G are spouted from the squish areas S and T, respectively. The squish flow F spouted from the squish area S flows towards the front face 20 of the raised portion 17, and the squish flow G spouted from the squish area T moves forward towards the recess 22. Then, the squish flow G impinges upon the semi-cylindrical wall 23, and a microturbulence is thus created in the recess 22. On the other hand, the squish flow F flowing towards the front face 20 of the raised portion 17 from the squish area 5 moves forward along the front face 20 of the raised portion 17 and then comes into violent contact with the squish flow G spouted from the squish area T. As a result of this violent contact, the flow direction of the squish flow G is changed so that the squish flow G flows along the top face 14 of the combustion chamber 5 as illustrated by the arrow H in FIG. 1. At this time, since the flow direction of the squish flow F is changed by the steeply inclined side wall 16b of the raised portion 16, the squish flow F also flows along the top face 14 of the combustion chamber 5 as illustrated by the arrow H in FIG. 1. By forming the steeply inclined side wall 16b which extends upwards from the ridge 21 of the raised portion 17, the squish flow G is not considerably decelerated by the squish flow F, and the squish flow F itself is also not considerably decelerated. Then, the squish flow H flowing along the top face 14 of the combustion chamber 5 passes in front of the recess 22 and moves downwards along the vertical side wall 15. At this time, since the electrode 11 of the spark plug 10 is arranged within the recess 22, the squish flow H does not inpinge directly upon the electrode 11 of the spark plug 10. Then, the squish flow H flowing downwardly along the vertical side wall 15 comes into violent contact with the squish flow F spouted from the squish area S; as a result, the flow direction of the squish flow F is changed as illustrated by the arrow I in FIG. 1. At this time, the squish flow G also flows along the flat bottom of the depression 19 as illustrated by the arrow I in FIG. 1. By forming the depression 19 in the top face of the piston 2, the squish flow F is not considerably decelerated by the squish flow H, and the squish flow F is also not considerably decelerated. Thus, a strong swirl motion, shown by the arrow K, which is rotating about the horizontal axis is created in the combustion chamber 5.

Then, the mixture is ignited by the spark plug 10. At this time, since a microturbulence is created in the recess 22 as mentioned previously, the mixture is easily ignited and then the flame rapidly spreads within the recess 22. After this, the flame swirls in the combustion chamber 5 together with the strong swirl motion K and the burning velocity is thus considerably increased. In addition, since the flame swirls in the combustion chamber 5, unburnt HC and CO located in the quench layers formed on the inner wall of the cylinder head 3 and on the top face of the piston 2 are burned. After this, when the downward movement of the piston 2 is started, the unburnt gas in the combustion chamber 5 is sucked into the squish areas S and T together with the flame. As a result, the unburnt HC and CO located in the quench layers formed on the inner wall of the cylinder head 3 and on the top face of the piston 2 within the squish areas S and T are burned.

In an internal combustion engine having such a construction that a swirl motion is created in the combustion chamber by the squish flow, the strength of the squish flow has a great influence on the strength of the swirl motion. In addition, the surface area of the squish area has a great influence on the strength of the squish flow. However, it is impossible to increase the surface area of the squish flow to a great extent in view of the construction of an engine. In addition, in the case wherein an excessively strong swirl motion is created in the combustion chamber, there is a danger in that a misfire will occur. As a result of experiments conducted by the inventor, in the engine illustrated in FIGS. 1 through 4, it has been proven that, in order to obtain an ease of ignition and a good combustion, it is preferably that a surface area ratio of the sum of the squish area formed on the inner wall of the cylinder head 3 and the squish area formed on the top face of the piston 2 to the sum of the cross-sectional area of the cylinder bore and the surface area of the inner wall of the cylinder head 3 except for the surface area of the vertical side wall 15 be in the range of 30 percent to 50 percent. In addition, it has also been proven that the best iginition and combustion can be obtained when the above-mentioned surface area ratio is in the range of 35 percent to 40 percent. In the present invention, in order to form squish areas S and T having a large surface area while forming the combustion chamber 5 as compact as possible, the squish area S must be so formed that it has an annular shape.

In addition, as mentioned previously, since the flat surface portion 12b of the cylinder head 3 has the width B which is wider than the width C of the flat surface portion 12c of the cylinder head 3, the squish flow spouted from the flat surface portion 12b as illustrated by the arrow Fb in FIG. 2 is stronger than that spouted from the flat surface portion 12c as illustrated by the arrow Fc in FIG. 2. In addition, as is illustrated by the broken lines Tb, Tc in FIG. 2, the squish area T is so formed that the surface area of the squish area portion Tb located near the exhaust valve 8 is considerably greater than that of the squish area portion Tc located near the intake valve 6; as a result, the squish flow Gb spouted from the squish area portion Tb is stronger than the squish flow Gc spouted from the squish area portion Tc. Consequently, a swirl motion which rotates about the horizontal axis and which is created in the combustion chamber 5 beneath the exhaust valve 8 by the pair of squish flows Fb, Gb becomes stronger than a swirl motion which rotates about the horizontal axis and which is created in the combustion chamber 5 beneath the intake valve 6 by the pair of squish flow, Fc, Gc. As is known to those skilled in the art, a knocking occurs due to the fact that the self-ignition of the mixture located near the exhaust valve 8 is caused. However, by creating a strong swirl motion in the combustion chamber 5 beneath the exhaust valve 8 and causing the flame of the mixture ignited by the spark plug 10 to propagate immediately towards the space around the exhaust valve 8, it is possible to prevent a knocking from occurring.

According to the present invention, since an optimum and strong swirl motion can be created in the combustion chamber, the burning velocity can be considerably increased. As a result, a stable combustion can be obtained, and a specific fuel consumption can be improved.

While the invention has been described with reference to a specific embodiment chosen for purposes of illustration, it should be apparent that numerous modifications can be made thereto by those skilled in the art without departing from the spirit and scope of the invention. 

What is claimed is:
 1. An internal combustion engine comprising:a cylinder block having a cylinder bore therein; a cylinder head mounted on said cylinder block and having an inner wall; a first raised portion having on its lower end a flat bottom face and being formed on the periphery of the inner wall of said cylinder head so as to project downwards; a piston reciprocally movable in said cylinder bore and having a top face which has a flat peripheral portion approachable to said flat bottom face, the inner wall of said cylinder head and the top face of said piston defining a combustion chamber therebetween, said first raised portion having a substantially vertical side wall exposed to the combustion chamber; an intake valve movably mounted on said cylinder head for leading a combustible mixture into said combustion chamber; an exhaust valve movably mounted on said cylinder head for discharging exhaust gas into the atmosphere; a spark plug having a spark plug recess located in said combustion chamber, said recess extending outwardly beyond a straight line extending between the peripheries of the intake and exhaust valves; a first squish area spouting out a first squish flow as said piston reaches the end of its compression stroke, said first squish area comprising an annular area between said flat peripheral portion of the top face of said piston and the flat bottom face of said cylinder head, said first squish area extending substantially along the entire periphery of said top face of said piston; a second raised portion formed on the top face of said piston at a position opposite to said first raised portion with respect to an axis of said piston and having a rear face and a front face exposed to said combustion chamber, said rear face being approachable to the inner wall of said cylinder head so as to create a second squish area therebetween at the end of the compression stroke for spouting out a second squish flow which moves foward in the upper interior of said combustion chamber in the direction opposite to the spouting direction of said first squish flow; said first and second squish flows cooperating with each other to create a strong swirl motion rotating about a horizontal axis in said combustion chamber, said first squish area extending inward from the periphery of said top face of said piston to a continuous sinuous inner periphery which extends around and is almost vertically under said intake valve, said exhaust valve, and said spark plug recess and adjacent to said second raised portion; a third raised portion formed on the inner wall of said cylinder head above said second raised portion and having a bottom wall which cooperates with said rear face of said second raised portion for creating said second squish area therebetween; and, a surface area ratio of the sum of said first and second squish areas formed on the inner wall of said cylinder head and said first and second squish areas formed on the top face of said piston to the sum of the cross-sectional area of said cylinder bore and the surface area of the inner wall of said cylinder head, except for the surface area of the vertical side wall of said first raised portion, being in the range of 30 percent to 50 percent.
 2. An internal combustion engine as claimed in claim 1, wherein said surface area ratio is in the range of 35 percent to 40 percent.
 3. An internal combustion engine as claimed in claim 1, wherein said first squish area extends along a periphery of the top face of said piston over the entire periphery thereof and has an annular shape.
 4. An internal combustion engine as claimed in claim 1, wherein said bottom wall of said third raised portion has a spherical shape, said rear face of said second raised portion having a shape which is complementary to the shape of said spherical bottom wall for creating a spherical shell shape squish area between said rear face and said spherical bottom wall.
 5. An internal combustion engine as claimed in claim 1, wherein said first raised portion has a horizontally flat bottom face, said first squish area extending in a horizontal plane.
 6. An internal combustion engine as claimed in claim 1, wherein said front face of said second raised portion is smoothly connected to said flat peripheral portion of the top face of said piston.
 7. An internal combustion engine as claimed in claim 6, wherein said front face of said second raised portion is formed so as to be flat.
 8. An internal combustion engine as claimed in claim 1, wherein said recess is formed on the inner wall of said cylinder head at a position remote from said second squish area and near said first raised portion.
 9. An internal combustion engine as claimed in claim 8, wherein said combustion chamber has a spherical top face, said recess being formed on said spherical top face.
 10. An internal combustion engine as claimed in claim 8, wherein said recess is arranged on an extension of said second squish area.
 11. An internal combustion engine as claimed in claim 8, wherein said recess has a vertically extending semi-cylindrical wall arranged on said extension of said second squish area. 